JP6799940B2 - Connection terminal for physical quantity detection sensor - Google Patents

Description

The present invention is a connection terminal for a physical quantity detection sensor that receives the electric quantity from a physical quantity detection sensor that detects a physical quantity at a predetermined location to be measured and converts it into an electric quantity, and relays the electric quantity to a physical quantity measuring device that determines the value of the physical quantity. And physical quantity measuring device.

Conventionally, a connection terminal for a physical quantity detection sensor that receives the physical quantity from a physical quantity detection sensor that detects a physical quantity generated at a predetermined location to be measured and converts it into an electric quantity and relays it to a physical quantity measuring device that determines the value of the physical quantity. It is used in various ways. Generally, a physical quantity detection sensor (hereinafter, may be abbreviated as "sensor") is installed in the field, and the physical quantity measuring device is located away from the sensor via the sensor and wiring (lead wire). It is connected and measured. Therefore, a terminal block for relaying wiring is installed between the sensor and the physical quantity measuring device.
Patent Document 1 (Japanese Unexamined Patent Publication No. 2004-340695) and Patent Document 2 (Japanese Unexamined Patent Publication No. 2007-333544) are known as techniques related to such a background.
For example, in Patent Document 1, a measurement mode automatic setting system and a measurement mode determination method in a strain gauge type measuring instrument, that is, a connection state of a strain gauge or the like to a plurality of predetermined terminals is detected from the measuring instrument side, and the corresponding measurement is performed. A method for determining the mode is described.

Specifically, the measurement mode automatic setting system according to Patent Document 1 is a measurement mode in a strain gauge type measuring instrument that selectively measures by a plurality of measurement modes in which the connection states of strain gauges to a plurality of predetermined terminals are different. In the automatic setting system, power is supplied to at least a part of a plurality of predetermined terminals to which the strain gauge is connected by switching the power supply path and the detection terminal, and the resistance value between the terminals is detected, and based on the resistance value between the terminals. A mode discriminating means for discriminating the measurement mode and
A measurement means that switches the measurement system based on the discrimination result by the mode discrimination means and performs measurement according to the measurement mode, and a measurement means.
Is provided, and the connection state and measurement mode of the measurement system using a strain gauge or the like are discriminated.

Further, Patent Document 2 provides a measurement circuit in which a non-linear error of a bridge circuit does not occur with respect to a strain measurement circuit by the 1-gauge method, and further, a constant current power source is used as a common power source in the 1-gauge method and 2 wires. A strain measurement circuit by the 1-gauge method that enables measurement by any of the connection methods of the type, 3-wire type, and 4-wire type, and can reduce the circuit scale, reduce the cost, and improve the work efficiency of the measurement is described. ing. Specifically, in Patent Document 2, the strain measurement circuit is provided with a plurality of changeover switches, and one constant current source is used, and a 1-gauge method 2-wire system 1 is used according to the on-off state of the switch. It is configured so that strain measurement can be performed by either a gauge method 3-wire system or a 1-gauge method 4-wire system.
FIG. 11 is a circuit diagram showing various circuit configurations in which a Wheatstone bridge circuit (hereinafter, may be referred to as a “bridge circuit”) is configured by using a conventional general strain gauge, and FIG. 11A is a circuit diagram. 11 (b) shows the configuration of the 1-gauge method 3-wire system, FIG. 11 (c) shows the configuration of the 2-gauge method, and FIG. 11 (d) shows the configuration of the 1-gauge method 3-wire system. ) Indicates the configuration of the strain gauge type sensor of the 4-gauge method (sometimes referred to as the full bridge method).

In the 1-gauge method 2-wire circuit configuration of FIG. 11A, a strain gauge Ra for detecting the amount of strain is connected to one side of the bridge circuit, and a fixed resistor is connected to the remaining three sides. This strain gauge detects strain and converts the resistance change that occurs into a voltage in the bridge circuit. In order to convert this resistance change into a voltage, it is necessary to apply a constant voltage or current to the bridge circuit to excite it.
In the circuit configuration of the 1-gauge method 3-wire system shown in FIG. 11B, the strain gauge Ra and the strain measuring device are connected by three lead wires, for example, the temperature influence of the lead wires can be removed, or the lead wires can be removed. It is not affected by the capacitance of.
The circuit configuration of the two-gauge method shown in FIG. 11C is formed by connecting two strain gauges Ra and Rb to two adjacent sides of the bridge circuit, and FIG. 11D shows strain gauges Ra and Rb. , Rc, Rd are connected to each side of the bridge circuit.
Further, in the conventional connection terminal 100, for example, as shown in FIG. 12, 5-pin connection terminals A, B, C, D, and E are arranged on the terminal block 101, and each terminal is provided on the terminal block 102. By screwing or soldering a Phillips screw (male screw) to the formed female screw, the end of the lead wire connected to the physical quantity detection sensor composed of a strain gauge or the like is connected and fixed.

Japanese Unexamined Patent Publication No. 2004-340695 JP-A-2007-333544

By the way, the conventional connection terminal for the physical quantity detection sensor has a problem to be solved as described below.
As described above, there are several methods for connecting the strain gauge to the physical quantity measuring device, such as the 1-gauge method, 2-wire system, 1-gauge method, 3-wire system, 2-gauge method, and 4-gauge method.
Further, in the case of supporting not only strain gauges but also voltage and thermocouple inputs, the voltage generation source and thermocouple were connected to the 5-pin terminal block, for example, the 2nd and 4th pins. ..
However, if a terminal block (connection terminal) having 5 pins is used, a large physical space is required, and the housing in which the terminal block is provided is inevitably large.
Further, when connecting the strain gauge type converter to the 5-pin terminal block 101, it is necessary to tighten or solder five screws in order to connect all five lead wires to the connection terminal 100.

In particular, for example, in the case of multi-channel measurement of several hundred points, it takes a lot of time to fasten or solder the five screws for the number of channels.
Further, when connecting a voltage generation source or a thermocouple, the connection destination of the terminal block becomes more complicated.
For example, in the case of a strain gauge, the connection destination of the 1-gauge method 2-wire system is the 1st pin (A terminal) and the 2nd pin (B terminal) of the 5-pin terminal block, whereas the connection destination of the thermocouple. Is the 2nd pin (B terminal) and the 4th pin (D terminal) of the pin terminal block.
As described above, the connection method is different between the strain gauge and the voltage or thermocouple, and the wiring is complicated, so that there is a problem that work efficiency is lowered and erroneous wiring is likely to occur.
In either of Patent Document 1 and Patent Document 2 described above, the above-mentioned problems have not been solved at all.

The present invention has been made in view of the above circumstances, and the first object is to input a physical quantity measuring device by downsizing the connection terminal for a physical quantity detection sensor (hereinafter, may be abbreviated as "connection terminal"). Space saving of the part is achieved, so that the multi-core connector can be used even for the physical quantity measuring device that could not be provided with the multi-core connector due to the miniaturization of the measuring instrument and the conventional housing structure. The second purpose is to reduce the troublesomeness of connecting a physical quantity detection sensor such as a strain gauge to the connection terminal, significantly shorten the wiring time, and prevent erroneous wiring as much as possible. To provide terminals .

In order to achieve the first object and the second object, the connection terminal for the physical quantity detection sensor of the present invention according to claim 1 includes a physical quantity detection circuit having a plurality of modes formed including the physical quantity detection sensor, a plurality of connection terminals of the relays connection wiring between the physical quantity measuring device, wherein the physical quantity detecting sensor to determine the value of the physical quantity received electricity amount detected,
A part of the plurality of connection terminals is a connector dedicated to the physical quantity detection circuit of the predetermined mode, and the other part of the plurality of connection terminals is a physical quantity detection of one or more types of modes different from the predetermined mode. The circuit is equipped with multiple individual connection terminals that are shared.
The common plurality of individual connection terminals consist of a first connection terminal, a second connection terminal, and a third connection terminal.
The dedicated connector is a first connection pin and a second connection connected to the first connection terminal, the second connection terminal, and the third connection terminal in the internal circuit of the physical quantity measuring device, respectively. A fourth connection pin having a pin and a third connection pin, and further connected to a second input end of the first AD converter in the internal circuit, and a fifth connection pin grounded in the internal circuit. Consists of
By selecting any of the plurality of modes, it is characterized in that it can be used by being connected to a physical quantity measuring device that forms a circuit according to a desired mode.

According to the invention of claim 1, first, the space of the connection terminal which is the input unit of the physical quantity measuring device is saved by downsizing the connection terminal for the physical quantity detection sensor, and therefore the measuring instrument is downsized. The multi-core connector can be used even for a physical quantity measuring device that is not provided with a multi-core connector due to the balance of the conventional housing structure. Second, a physical quantity detection sensor such as a strain gauge is used as a connection terminal. It is possible to provide a connection terminal for a physical quantity detection sensor that can reduce the troublesomeness of connection, significantly shorten the wiring time, and prevent erroneous wiring as much as possible .

It is a top view which shows the appearance structure of the connection terminal for a physical quantity detection sensor which concerns on 1st Embodiment of this invention. The methods (a), (b), (c), (d), (e), and (f) are methods for wiring and connecting the physical quantity detection sensor connection terminal according to the embodiment of the present invention and various physical quantity detection sensors. Of these, (a) is a connection method with a 1-gauge method 2-wire strain gauge, and (b) is a connection method with a 1-gauge method 3-wire strain gauge. ) Is a connection method with a 2-gauge strain gauge, (d) is a connection method with a strain gauge type sensor using four strain gauges, (e) is a connection method with a voltage generation source, and (f). Is an explanatory diagram conceptually showing a connection method with a thermocouple. It is a top view which shows the appearance structure of the connection terminal for a physical quantity detection sensor which concerns on 2nd Embodiment of this invention. It is a circuit diagram which shows the state which connected the physical quantity measuring apparatus which concerns on 3rd Embodiment of this invention, and the strain gauge of the 1 gauge method 2-wire type through a connection terminal. It is explanatory drawing which shows the correspondence relationship between the on / off state and the switching state of each of various measurement modes (modes 1 to 6) and a plurality of switches (switch SW1 to switch SW7) in a physical quantity measuring apparatus. It is a circuit diagram which shows the state which connected the physical quantity measuring apparatus which concerns on 3rd Embodiment of this invention, and the strain gauge of the 1-gauge method 3-wire type through a connection terminal. It is a circuit diagram which shows the state which connected the physical quantity measuring apparatus which concerns on 3rd Embodiment of this invention, and the strain gauge of a 2-gauge method through a connection terminal. It is a circuit diagram which shows the state which connected the physical quantity measuring apparatus which concerns on 3rd Embodiment of this invention, and the strain gauge type sensor which uses four strain gauges through a connection terminal. It is a circuit diagram which shows the state which connected the physical quantity measuring apparatus which concerns on 3rd Embodiment of this invention, and a voltage generation source through a connection terminal. It is a circuit diagram which shows the state which connected the physical quantity measuring apparatus which concerns on 3rd Embodiment of this invention, and a thermocouple through a connection terminal. It is a circuit diagram which shows the structure of various bridge circuits including a strain gauge, and (a) is a 1-gauge method two-wire type bridge circuit diagram which was constructed by using one strain gauge. Yes, (b) is a 1-gauge method 3-wire bridge circuit configured using one strain gauge, and (c) is a 2-gauge method configured using two strain gauges. It is a bridge circuit diagram, and (d) is a circuit diagram of a strain gauge type sensor including a bridge circuit of the full bridge method configured by using four strain gauges. It is a top view which shows the appearance structure of the conventional 5-pin connection terminal.

Hereinafter, the present invention will be described through embodiments of the present invention, but the following embodiments do not limit the invention within the scope of the claims, and also combine the features described in the embodiments. Not all are essential to the solution of the invention.

[First Embodiment]
Next, a plurality of embodiments of the physical quantity detection sensor connection terminal and the physical quantity measuring device according to the present invention will be sequentially described.
FIG. 1 is a plan view showing an external configuration of a connection terminal for a physical quantity detection sensor according to the first embodiment of the present invention.
The connection terminal for the physical quantity detection sensor of the present embodiment relays the wiring between the physical quantity detection detection circuit including the physical quantity detection sensor and the physical quantity measuring device (physical quantity measuring device according to the present invention described later) that determines the value of the physical quantity. Multiple connection terminals to be connected.
In FIG. 1, the physical quantity detection sensor connection terminal (terminal block 12) of the first embodiment according to the present invention can be screwed (and / or soldered) to a multi-core connector 11 composed of a plurality of pins. It is provided with a plurality of connection terminals (121).
The connection terminals 121 (connection terminals A to C) of the terminal block 12 can be screwed (and / or soldered). It is also possible to solder these connection terminals after screwing them together.

The multi-core type connector 11 generally has a plurality of pins (holes), but in the figure, the connector 11 has 7 pins. Further, as the multi-core type connector 11, various commercially available products can be used, and for example, one conforming to NDIS (Non-Destructive Inspection Standard, Japan Nondestructive Inspection Association standard) can be used.
The connector 11 is a connector (dedicated connector) for connecting a dedicated fixed wiring to a predetermined first physical quantity detection circuit (corresponding to a bridge circuit of the full bridge method) including a sensor.
The predetermined first physical quantity detection circuit including the sensor is a bridge circuit including four strain gauges, and is characterized in that the connection wiring connected to the outside is fixed. For example, as shown in FIG. 11D, a gauge circuit in which strain gauges Ra, Rb, Rc, and Rd as physical quantity detection sensors are arranged on each of the four sides of the bridge circuit is applicable.

On the other hand, the plurality of connection terminals (connection terminals A to C) of the terminal block 12 share one or more types of second physical quantity detection circuits different from the predetermined first physical quantity detection circuit. It is a connection terminal to be selectively connected. The second physical quantity detection circuit is an electric circuit which is not limited to any kind, and is an electric circuit which needs to be selectively connected to a measuring device (for example, a physical quantity measuring device). For example, as shown in FIGS. 11A, 11B, and 11C, a gauge circuit in which a physical quantity detection sensor is arranged on one or two sides of a bridge circuit is used. In addition, it may be an arbitrary electric circuit which is not limited to a sensor, and can be connected to a voltage generation source such as a thermocouple or a battery, for example.
The first physical quantity detection circuit is a predetermined limited circuit as shown in FIG. 11B, and since the wiring to be connected is fixed as described above, there is no risk of erroneous connection.
On the other hand, since it is necessary to selectively connect the second physical quantity detection circuit [multiple modes (see FIGS. 11A, 11B, 11C)] to the physical quantity measuring device, the connection terminal (see By connecting to the connection terminals A to C), the degree of freedom in wiring can be ensured. Further, since the number of pin terminals is reduced as compared with the conventional case, the rate of erroneous connection can be reduced.

FIG. 2 is an explanatory diagram showing a method of wiring and connecting a connection terminal for a physical quantity detection sensor according to an embodiment of the present invention and a physical quantity detection circuit of a plurality of modes formed including various physical quantity detection sensors.
FIG. 2A shows a two-wire wiring between the sensor 31 including one strain gauge Ra on one side of the bridge circuit and the connection terminals (A, B) of the terminal block 12 (or 22). Shows the connection method. FIG. 2B shows a 1-gauge method 3 in which the sensor 32 including one strain gauge Ra on one side of the bridge circuit and the connection terminals (A, B, C) of the terminal block 12 (22) are connected. The wire type wiring connection method is shown. Further, FIG. 2C shows a sensor 31 (a) having a strain gauge Ra arranged on one side of the bridge circuit and a sensor 31 (b) having a strain gauge Rb arranged on the other side. The wiring connection method between the terminal block 12 (22) and the pin terminals (A, B, C) of the terminal block 12 (22) is shown.
Further, FIG. 2D shows each sensor of the strain gauge type sensor 33 and the pin of the multi-core type connector 11 as a physical quantity detection circuit in which strain gauges Ra, Rb, Rc, and Rd are arranged on each of the four sides of the bridge circuit. The wiring connection method with the terminal (11a to 11d) is shown. FIG. 2E shows a wiring connection method between the voltage generation source 34 such as a battery and the connection terminals (A, B) of the terminal block 12 (22). FIG. 2F shows a wiring connection method between the thermocouple 35 and the connection terminals (A, B) of the terminal block 12 (22).

[Second Embodiment]
FIG. 3 is a plan view showing an external configuration of a connection terminal for a physical quantity detection sensor according to a second embodiment of the present invention.
The connection terminal for the physical quantity detection sensor of the second embodiment is between a physical quantity detection detection circuit including the physical quantity detection sensor and a physical quantity measuring device (a physical quantity measuring device according to the present invention described later) for determining the value of the physical quantity. It is a plurality of connection terminals for relay connection of wiring.
In FIG. 3, the connection terminals for the physical quantity detection sensor of the second embodiment include a multi-core type connector 11 having a plurality of pins and a screwable connection terminal 221 (connection terminal A, connection terminal B, connection terminal). C) and.
The connection terminal 221 can be attached to and detached from the wiring end with a single touch. For example, it can be configured as a plug-in type.

[Third Embodiment]
FIG. 4 is a circuit diagram showing a circuit configuration of a physical quantity measuring device according to a third embodiment of the present invention and a wiring connection between a strain gauge which is a physical quantity detection sensor arranged externally and a connection terminal. The right part shown by the X-ray broken line shows the circuit configuration of the physical quantity measuring device, and the left part shown by the X-X line broken line shows the 1-gauge method 2-wire strain gauge (sensor 31) and the terminal block 12 (22). Is shown.
The physical quantity measuring device according to the third embodiment shown in FIG. 4 is provided with on / off switches (switch SW1 to switch SW7 in this case) at a plurality of locations in the internal wiring, and has one or more measurement modes (modes 1 to 1 in this case). Mode 6) is realized by configuring a circuit corresponding to the binary state or the switching state of the on / off switch.
FIG. 5 is an explanatory diagram showing a correspondence relationship between various measurement modes (modes 1 to 6) in the physical quantity measuring device and on / off states and switching states of each of the plurality of switches (switches SW1 to switch SW7).
Here, the relationship between the internal circuit of the physical quantity measuring device and each switch will be described with reference to the circuit diagram of FIG. 4 and the explanatory diagram of FIG.

The physical quantity measuring device 20 that is connected to a physical quantity detection circuit including the physical quantity detection sensor 31 to determine the value of the physical quantity is
A first switch SW1 provided in a path for supplying a high potential power supply from a power source ei to a first connection terminal A via a first operational amplifier Ic1a, a second connection terminal B, and a first AD converter. A second switch SW2 provided between the first input terminal of 1 and
A third switch SW3 provided between the second connection terminal B and the third connection terminal C, and
A fifth connected in series between the third connection terminal C and a low-potential power supply (a power supply divided by a resistor R1 and a resistor R2 with respect to the power supply ei) via a second operational amplifier Ic1b. A changeover switch SW4 which is arranged side by side with respect to the fixed resistor R5 and switches between a first section SW4b which connects the fifth fixed resistor R5 to one side of the bridge circuit and a second section SW4c which does not connect.
A fifth provided between the midpoint between the third fixed resistor R3 and the fourth fixed resistor R4 forming a part of the bridge circuit and the second input end of the first AD converter 1. Switch (SW5) and
Have,
The internal circuit is subjected to the 1-gauge method 2 by the on / off operation of the first switch SW1, the second switch SW2, the third switch SW3, the fifth switch SW5, and the switching operation of the changeover switch SW4. It is configured so that any mode of a linear mode, a 1-gauge method 3-wire mode, a 2-gauge method mode, and a full bridge method mode can be formed.

Further, the physical quantity measuring device 20 includes a switch connected between the first connection terminal A and the third input terminal of the first AD converter 1, the second connection terminal B, and the internal circuit. The first interlocking switch as the sixth switch SW6, which consists of a switch connected to the common potential of
A switch provided between the first connection terminal A and the first input terminal of the second AD converter 2, the second connection terminal B, and the second input terminal of the second AD converter 2. It also has a second interlocking switch as a seventh switch SW7 consisting of a switch provided between and.
On / off operation of the first switch SW1, the second switch SW2, the third switch SW3, the fifth switch SW5, the sixth switch SW6 and the seventh switch SW7, and the changeover switch SW4. The internal circuit is configured to switch to the measurement mode of the voltage generation source or the thermoelectromotive force measurement mode by the switching operation of.

How each such switch operates in each mode will be described below.
In the electric circuit of FIG. 4, as the case of mode 1 shown in FIG. 5, as shown in FIG. 11A, in the case of "1 gauge method 2-wire system" in which one strain gauge is arranged on one side of the bridge circuit. The circuit configuration of is shown.
In the case of this 1-gauge method 2-wire system measurement, the first switch SW1 and the second connection terminal B that control the power supply path from the power supply (high potential side) ei to the first connection terminal A via the operational amplifier Ic1a. A second switch SW2 that controls the output path from the first AD converter 1 to the first input terminal, and a third that controls a short circuit between the second connection terminal B and the third connection terminal C. The switch SW3, the fifth switch SW5 that controls energization between the connection point between the fixed resistors R3 and R4 of the bridge circuit and the second input end of the first AD converter 1 are all turned on.
On the other hand, the switch SW6 and the switch SW7 are turned off, and the changeover switch SW4 is set so as to conduct electricity between the common terminal SW4a and the first terminal SW4b.
With the above settings, a strain gauge (sensor 31) is connected between the first connection terminal A and the second connection terminal B of the terminal block 12 (terminal block 22 in the second embodiment). ..

The bridge voltage output from the power supply ei via the first operational amplifier IC1a is applied to the first connection terminal A of the terminal block 12 (22) via the first switch SW1. At this time, the bridge current flows in the order of the first connection terminal A of the terminal block 12 (22) → the strain gauge (sensor 31) → the second connection terminal B of the terminal block 12 (22), and further, the third connection terminal B. It flows to the second operational amplifier IC1b via the switch SW3 and the resistor R5.
The output of the strain gauge (sensor 31) at this time is measured by the first AD converter 1. However, there are two routes to the input to the first AD converter 1, one of which is the first from the second connection terminal B of the terminal block 12 (22) via the second switch SW2. It is a route that is input to the AD converter 1. The other one is input from the intermediate point (connection point) between the resistors R3 and R4 constituting the bridge circuit to the second input end of the first AD converter 1 via the fifth switch SW5. Route. The output voltage value (output of the strain gauge (sensor 31)) measured by the first AD converter 1 can be converted into a strain amount by a strain measuring device or an appropriate computer process.

FIG. 6 is a circuit diagram showing a circuit configuration in another mode of the physical quantity measuring device according to the third embodiment of the present invention and a wiring connection with a strain gauge (sensor 31) which is a physical quantity detection sensor. The internal circuit configuration of the physical quantity measuring device is shown on the right side of the broken line in the direction, and the 1-gauge method 3-wire strain gauge (sensor 31) and the terminal block 12 (22) are shown on the left side of the XX broken line. Shown.
The electric circuit of FIG. 6 shows a circuit configuration as a physical quantity detection circuit in the case of the 1-gauge method 3-wire system in which a sensor is arranged on one side of the bridge circuit as in the case of mode 2 shown in FIG.
In the case of this 1-gauge method 3-wire system measurement, the first switch SW1, the second switch SW2, and the fifth switch SW5 are turned on, and the third switch SW3, the sixth switch SW6, and the seventh switch The switch SW6 is turned off, and the changeover switch SW4 is set so as to conduct conduction between the common terminal SW4a and the first section SW4b.

With the above settings, the strain gauge (sensor 31) is connected to the first connection terminal A, the second connection terminal B, and the third connection terminal C of the terminal block 12 (22). The bridge voltage ei output via the first operational amplifier IC1a is applied to the first connection terminal A of the terminal block 12 (22) via the first switch SW1. At this time, the bridge current flows in the order of the first connection terminal A of the terminal block 12 (22) → the strain gauge (sensor 31) → the third connection terminal C of the terminal block 12 (22), and further applies the resistor R5. It flows to the second operational amplifier IC1b via.
The output of the strain gauge (sensor 31) at this time is measured by the first AD converter 1. However, there are two routes to the input to the first AD converter 1, one of which is the first from the second connection terminal B of the terminal block 12 (22) via the second switch SW2. It is input to the AD converter 1. The other one is input to the first AD converter 1 from the midpoint between the resistors R3 and R4 constituting the bridge circuit via the fifth switch SW5. The voltage value (output of the strain gauge (sensor 31)) measured by the first AD converter 1 can be converted into a strain amount by appropriate computer processing.

FIG. 7 shows the circuit configuration of the mode 3 two-gauge method of the physical quantity measuring device according to the third embodiment of the present invention and the wiring connection with the physical quantity detection circuit including two strain gauges (sensors 31a and 31b). In the circuit diagram, the part on the right side of the XX line shows the internal circuit configuration of the physical quantity measuring device, and the part on the left side of the XX broken line shows two strain gauges (sensor 31 (a). )), The sensor 31 (b) and the terminal block 12 (22) are shown.
In the electric circuit of FIG. 7, the circuit configuration in the case of the mode 3 shown in FIG. 5 in the case of the two-gauge method using two strain gauges in which sensors are arranged on two adjacent sides of the bridge circuit is shown.
In the case of measurement by this two-gauge method, the first switch SW1, the second switch SW2, and the fifth switch SW5 are turned on, respectively, and the third switch SW3, the sixth switch SW6, and the seventh switch SW7 are each turned on. Is turned off, and the changeover switch SW4 is set so as to conduct conduction between the common terminal SW4a and the second section SW4c.

With the above settings, strain gauges (sensors 31 (a) and 31 (b)) are connected to the first connection terminal A, the second connection terminal B, and the third connection terminal C of the terminal block 12 (22). To. The bridge voltage output from the first operational amplifier IC1a is applied to the first connection terminal A of the terminal block 12 (22) via the first switch SW1. At this time, the bridge current is the first connection terminal A of the terminal block 12 (22) → strain gauge (sensor 31 (a)) → second connection terminal B → strain gauge (sensor 31 (b)) → terminal block. It flows in the order of the third connection terminal C of 12 (22), and further flows to the operational amplifier IC1b via the resistor R5.
At this time, since the common terminal SW4a of the changeover switch SW4 and the intercept SW4c are short-circuited, the second operational amplifier amplifier IC1b outputs a voltage that is not affected by the voltage drop due to the resistor R5. The output of the strain gauges (sensor 31 (a), sensor 31 (b)) at this time is measured by the first AD converter 1. However, there are two routes to the input to the first AD converter 1, one of which is the first from the second connection terminal B of the terminal block 12 (22) via the second switch SW2. It is input to the AD converter 1. The other one is input from the midpoint between the resistors R3 and R4 to the second input terminal of the first AD converter 1 via the fifth switch SW5. The voltage value (output of the strain gauge (sensor 32)) measured by the first AD converter 1 can be converted into a strain amount by appropriate computer processing.

FIG. 8 is a circuit diagram showing the circuit configuration of the strain gauge type sensor mode of the physical quantity measuring device according to the third embodiment of the present invention and the wiring connection with the external physical quantity detection circuit, with the XX broken line in between. The right part shows the circuit configuration of the physical quantity measuring device, and the left part across the XX broken line is the first connection pin 11a to the fourth connection pin 11d composed of a dedicated connector and four strain gauges. The connection state between Ra to Rd and the terminal block 12 (22) is shown.
In the electric circuit of FIG. 8, in the case of mode 4 shown in FIG. 5 (in the case of a strain gauge type sensor), a circuit configuration for measuring with a sensor 33 in which strain gauges Ra to Rd are arranged on four sides of the bridge circuit is shown. ..
When measuring with this detection sensor 33 (strain gauge type sensor), the first switch SW2 and the second switch SW2 are turned on, and the third switch SW3, the fifth switch SW5, the sixth switch SW, and the third switch SW2 are turned on. The switch SW7 of No. 7 is turned off, and the changeover switch SW4 is set so as to conduct electricity between the common terminal SW4a and the second section SW4c.

With the above settings, the strain gauge type sensor 33 is connected to the multi-core type connector 11 of the terminal block 12 (22). The bridge voltage output from the first operational amplifier IC1a is applied to the first connection pin A (11a) of the connector 11 via the first switch SW1. At this time, the bridge current is the connection pin A (11a) of the connector 11 → the strain gauge Ra of the strain gauge type sensor 33 → the second connection pin B (11b) → the strain gauge Rb → the third pin C of the connector 11 ( It flows in the order of 11c), and further flows to the second operational capacitor IC1b.
At this time, since the common terminal SW4a of the changeover switch SW4 and the second intercept SW4c are short-circuited, the operational amplifier IC1b outputs a voltage that is not affected by the voltage drop due to the resistor R5. The output of the strain gauge 33 at this time is measured by the first AD converter 1. However, there are two routes to the input to the first AD converter 1, one of which is the first from the second pin terminal B (12b) of the terminal block 12 (22) via the switch SW2. It is input to the AD converter 1. The other one is input from the midpoint between the strain gauges Rc and Rd to the first AD converter 1 via the fourth pin D (11d). The voltage value measured by the first AD converter 1 can be converted into physical quantities such as load, pressure, acceleration, and displacement torque by appropriate computer processing.

FIG. 9 is a circuit diagram showing the internal circuit configuration of mode 5 of the physical quantity measuring device according to the third embodiment of the present invention and the wiring connection with the physical quantity detection circuit, and is a portion on the right side of the XX broken line. Indicates the circuit configuration of the physical quantity measuring device, and the portion on the left side of the XX broken line indicates the connection state between the voltage generation source 34 and the terminal block 12 (22).
In the electric circuit of FIG. 9, the circuit configuration in the case of measuring the voltage generated from the voltage generation source 34 is shown as the case of the mode 5 shown in FIG.
When measuring the voltage generated from the voltage generation source 34, the fifth switch SW5 and the sixth switch SW6 are turned on, and the first switch SW1, the second switch SW2, the third switch SW3, and the seventh switch The switch SW7 is turned off, and the changeover switch SW4 is set so as to conduct electricity between the common terminal SW4a and the first section SW4b.
With the above settings, the voltage of the voltage generation source 34 is input from the first connection terminal A and the second connection terminal B of the terminal block 12 (22), and the value is measured by the first AD converter 1. In this case, the input from the first connection terminal A of the terminal block 12 (22) is input to the first AD converter 1 via the sixth switch SW6. On the other hand, the input from the second connection terminal B of the terminal block 12 (22) is also connected to the common potential in the circuit of the physical quantity measuring device shown in FIG. 9 via the sixth switch SW6.

FIG. 10 is a circuit diagram showing a circuit configuration of mode 6 of the physical quantity measuring device according to the third embodiment of the present invention and a wiring connection with a thermocouple as a physical quantity detection sensor, and is on the right side with an XX broken line in between. The part shown in is the circuit configuration of the physical quantity measuring device, and the part on the left side of the XX broken line shows the connection state between the thermocouple 35 and the terminal block 12 (22).
In the electric circuit of FIG. 10, the circuit configuration in the case of measuring the ambient temperature by the thermocouple 35 is shown as the case of the mode 6 shown in FIG.
When the temperature is measured by the thermocouple 35, the fifth switch SW5 and the seventh switch SW7 are turned on, and the first switch SW1, the second switch SW2, the third switch SW3, and the sixth switch SW6 are turned on. Is turned off, and the changeover switch SW4 is set so as to conduct electricity between the common terminal SW4a and the first section SW4b.
With the above settings, the electromotive force (voltage) of the thermocouple 35 is input from the first connection terminal A and the second connection terminal B of the terminal block 12 (22), and the second AD is passed through the seventh switch SW7. It is input to the converter 2. In the second AD converter 2, the electromotive force (voltage) of the thermocouple 35 can be measured from this input and converted into the ambient temperature by appropriate computer processing.

As described above, among the connection terminals for the physical quantity detection sensor according to the present invention, in the strain gauge type sensor, the first connection pin A to the fourth connection pin D of the terminal block 12 (22) are Since the connection wiring to be connected to the physical quantity measuring device is fixed (specified) via the multi-core connector (preferably NDIS connector) 11, the connection work with the terminal block 12 is simplified, and the work efficiency is improved. It is possible to prevent erroneous wiring. Further, the three terminals of the first connection terminal A, the second connection terminal B, and the third connection terminal C in the terminal block are used in a 1-gauge method 2-wire mode, a 1-gauge method 3-wire mode, and a 2-gauge method mode. Can be shared (corresponding) to each of them, which can contribute to space saving and efficiency improvement of work efficiency.
In addition, other measurement modes in which the connection wiring connected to the physical quantity measuring device as a physical quantity detection sensor is not fixed, that is, 1 gauge method 2-wire mode, 1 gauge method 3-wire mode, 2-gauge method mode, thermocouple measurement. Equal quantity For the object to be measured, it is sufficient to connect to the connection terminals (first connection terminal A to third connection terminal C), which has fewer connection terminals than before, so wiring is free. It is possible to secure the degree and reduce the rate of erroneous connection.

Further, as described above, the physical quantity measuring device according to the present invention can set the on / off state or the switching state of the switches in the circuit as a predetermined combination corresponding to the measurement mode, and is common. Since the wiring connection with the usable terminal block 12 (22) is also defined as a predetermined connection method, it is not necessary to use various physical quantity devices having various specifications, and the possibility of erroneous wiring is reduced. Can be done.
The on / off control and the switching control of the first switch SW1 to the seventh switch SW7 are selected according to the first mode to the sixth mode according to the combination shown in FIG. It is configured so that it can be set easily and surely according to the (multi-core) of the selected mode.
The gist of the physical quantity detection sensor connection terminal and the physical quantity measuring device connected to the connection terminal according to the present invention can be summarized as follows.

First, the physical quantity detection sensor connection terminal of the present invention determines the physical quantity detection circuit of the plurality modes formed including a physical quantity detecting sensor, the value of the physical quantity received the amount of electricity the physical quantity detecting sensor detects At multiple connection terminals that relay and connect the wiring to and from the physical quantity measuring device
A part of the plurality of connection terminals is a connector dedicated to the physical quantity detection circuit of the predetermined mode, and the other part of the plurality of connection terminals is a physical quantity detection of one or more types of modes different from the predetermined mode. The circuit is equipped with multiple individual connection terminals that are shared.
The common plurality of individual connection terminals consist of a first connection terminal, a second connection terminal, and a third connection terminal.
The dedicated connector is a first connection pin and a second connection connected to the first connection terminal, the second connection terminal, and the third connection terminal in the internal circuit of the physical quantity measuring device, respectively. A fourth connection pin having a pin and a third connection pin, and further connected to a second input end of the first AD converter in the internal circuit, and a fifth connection pin grounded in the internal circuit. Consists of
By selecting any of the plurality of modes, it is characterized in that it can be used by being connected to a physical quantity measuring device that forms a circuit according to a desired mode (corresponding to claim 1). ..
Further, it is desirable that the dedicated connector of the physical quantity detection sensor connection terminal of the present invention is a multi-core type connector (corresponding to claim 5).

Further, in the shared individual plurality of connection terminals of the connection terminal for the physical quantity detection sensor of the present invention, any one of three screw terminals, a solder terminal or a one-touch type pin terminal is close to the connector and is a terminal block. It is desirable that it is arranged in (corresponding to claim 6 ).
Further, it is desirable that the physical quantity detection circuit of the predetermined mode of the physical quantity detection sensor connection terminal of the present invention is a full bridge detection circuit formed by including strain gauges on the four sides of the bridge circuit (claim 7 ). Corresponding).
Further, the physical quantity detection circuit of one or more types of a plurality of modes different from the predetermined mode of the connection terminal for the physical quantity detection sensor of the present invention is a 1-gauge method 2-wire mode formed including a strain gauge, and 1 gauge. 3-wire mode, even in the detection circuit of any of the mode of 2 gauge method mode not good.

Further, the physical quantity detection circuit of one or more types of a plurality of modes different from the predetermined mode of the connection terminal for the physical quantity detection sensor of the present invention includes a temperature detection mode or a voltage generation source formed including a thermocouple. but it may also be either a physical quantity detection circuit of the voltage detection mode to be formed.
Further, the physical quantity detection sensor of the predetermined mode of the connection terminal for the physical quantity detection sensor of the present invention is configured by using a strain gauge that changes the resistance value in response to any of pressure, acceleration, vibration, displacement, load, and torque. It is desirable that the strain gauge type converter is used (corresponding to claim 8 ) .

Further, by connecting one of the two lead wires of one strain gauge of the physical quantity detection sensor connection terminal of the present invention to the first connection terminal and the other to the second connection terminal, 1 A gauge method 2-wire physical quantity detection circuit was formed.
The lead wire connected to one end side of one strain gauge is connected to the first connection terminal, and one of the two lead wires connected to the other end side is connected to the second connection terminal. By connecting the other to the third connection terminal, a 1-gauge 3-wire physical quantity detection circuit is formed.
Of the two strain gauges, the two lead wires of one of the strain gauges are connected to the first connection terminal and the second connection terminal, respectively.
By connecting the two lead wires of the other strain gauge to the second connection terminal and the third connection terminal, respectively, a physical quantity detection circuit of a two-gauge method is formed.
One of the two leads of the voltage source, connected to said first connection terminal and connecting the other to the second connection terminal, the physical quantity detection circuit for detecting the voltage of the voltage source Formed,
One of the two leads of the thermocouple, connect the other connected to the first connection terminal to said second connecting terminal, as a physical quantity detecting circuit including a thermocouple is formed Also good (corresponding to claim 2).

Further, in the connection terminal for the physical quantity detection sensor of the present invention, one of the two lead wires of the first strain gauge among the four strain gauges connected to the multi- core type connector is connected to the first connection pin. Connect and connect the other to the second connection pin
One of the two leads of the second strain gauge is connected to the second connecting pin, the other is connected to the third connecting pin, and one of the two leads of the third strain gauge is connected. Connect to the third connection pin and connect the other to the fourth connection pin.
By connecting one of the two lead wires of the fourth strain gauge to the fourth connection pin and the other to the first connection pin, a physical quantity detection circuit of the full bridge method is formed. (Corresponding to claim 3).
Further, the connection terminal for the physical quantity detection sensor of the present invention is provided with an on / off switch and a changeover switch at one or more points of the internal wiring, and two or more measurement modes can be set to the binary state of the plurality of on / off switches. By forming a circuit corresponding to the switching state of the changeover switch, a predetermined wiring is made with the physical quantity measuring device configured so that the value of the physical quantity can be determined in a desired mode (claim 4). Corresponding).

Further, the physical quantity measuring device of the present invention is a physical quantity measuring device that determines a value of the physical quantity by connecting to a physical quantity detecting circuit including a physical quantity detecting sensor via a connection terminal for the physical quantity detecting sensor.
A first switch provided in a path for supplying a high-potential power supply to the first connection terminal, and a first switch provided between the second connection terminal and the first input terminal of the first AD converter. 2 switches and
A third switch provided between the second connection terminal and the third connection terminal,
With the first section parallel to the fifth fixed resistor connected in series between the third connection terminal and the low potential power supply and connecting the fifth fixed resistor to one side of the bridge circuit. A changeover switch to switch between the second section that is not connected,
A fifth switch provided between an intermediate point between a third fixed resistor and a fourth fixed resistor forming a part of the bridge circuit and a second input end of the first AD converter, and a fifth switch.
Have,
Said first switch, said second switch, said third switch, the switching operation of the fifth switch on / off operation and the switching example switches, 1 gage method 2-wire mode, 1 gauge method 3 line type mode, 2 gauge method mode, it is characterized by being configured so as to form one of the modes of a full bridge method mode.

Further, the physical quantity measuring device of the present invention turns on the first switch, the second switch, the third switch, and the fifth switch, and switches the changeover switch to the first section side. Accordingly, Ru can be an internal circuit forming a mode of the 1 gage method 2-wire.

Further, in the physical quantity measuring device of the present invention, the first switch, the second switch, and the fifth switch are turned on, the third switch is turned off, and the changeover switch is placed on the first section side. By switching
It said internal circuit, Ru can be formed in the mode of the 1 gage method 3-wire.
Further, in the physical quantity measuring device of the present invention, the first switch, the second switch, and the fifth switch are turned on, the third switch is turned off, and the changeover switch is placed on the second section side. By switching
Wherein the internal circuit, it is Ru can configured to form a mode of the 2 gauge method.
Further, in the physical quantity measuring device of the present invention, the first switch and the second switch are turned on, the third switch and the fifth switch are turned off, and the changeover switch is set on the second section side. By switching to
It said internal circuit, Ru can be formed in the mode of the full bridge.

Further, the physical quantity measuring device of the present invention includes a switch connected between the first connection terminal and the third input terminal of the first AD converter, the second connection terminal, and the internal circuit. A first interlocking switch consisting of a switch connected to a common potential,
A switch provided between the first connection terminal and the first input terminal of the second AD converter, and between the second connection terminal and the second input end of the second AD converter. It also has a second interlocking switch consisting of the provided switch,
The inside by the on / off operation of the first switch, the second switch, the third switch, the fifth switch, the sixth switch and the seventh switch, and the switching operation of the changeover switch. circuit, but it may also be configured so switched to the measurement mode or thermoelectromotive power measurement mode of the voltage source.

Further, the physical quantity measuring device of the present invention turns on the fifth switch and the sixth switch, and turns off the first switch, the second switch, the third switch, and the seventh switch. and then, the by switching the changeover switch to the first section side, the internal circuit, but it may also be configured so switched to the measurement mode of the voltage source.
Further, the physical quantity measuring device of the present invention turns on the fifth switch and the seventh switch, and turns off the first switch, the second switch, the third switch and the sixth switch. and then, the by switching the changeover switch to the first section side, the internal circuit, but it may also be configured so switched to the measurement mode of the thermoelectromotive force due to the thermocouple.

1 1st AD converter 2 2nd AD converter 11 Connector (multi-core type)
12, 22 Terminal block A 1st connection terminal B 2nd connection terminal C 3rd connection terminal 11a 1st connection pin 11b 2nd connection pin 11c 3rd connection pin 11d 4th connection pin 11e 5th Connection pin 11f 6th connection pin 20 Physical quantity measuring device 31, 32, 31 (a), 31 (b) Sensor (strain gauge)
33 Strain gauge type sensor 34 Voltage source 35 Thermocouple Ra, Rb, Rc, Rd Strain gauge R1, R2 resistance R3, R4, R5 Bridge resistance (fixed resistance)
1C1a 1st operational amplifier 1C1b 2nd operational amplifier SW1 to SW7 1st to 7th switches ei Power supply

Claims (8)

A physical quantity detection circuit of the plurality modes formed including a physical quantity detecting sensor, a plurality of relay connecting wiring between the physical quantity measuring device, wherein the physical quantity detecting sensor to determine the value of the physical quantity received electricity amount detected At the connection terminal of
A part of the plurality of connection terminals is a connector dedicated to the physical quantity detection circuit of the predetermined mode, and the other part of the plurality of connection terminals is a physical quantity detection of one or more types of modes different from the predetermined mode. The circuit is equipped with multiple individual connection terminals that are shared.
The common plurality of individual connection terminals consist of a first connection terminal, a second connection terminal, and a third connection terminal.
The dedicated connector is a first connection pin and a second connection connected to the first connection terminal, the second connection terminal, and the third connection terminal in the internal circuit of the physical quantity measuring device, respectively. It has a pin and a third connection pin, and further comprises a fourth connection pin connected to the input end of the AD converter in the internal circuit and a fifth connection pin grounded in the internal circuit.
A connection terminal for a physical quantity detection sensor, which is configured so that it can be used by being connected to a physical quantity measuring device that forms a circuit according to a desired mode by selecting any of the plurality of modes. By connecting one of the two lead wires of one strain gauge to the first connection terminal and the other to the second connection terminal, a 1-gauge method 2-wire physical quantity detection circuit is formed. ,
The lead wire connected to one end side of one strain gauge is connected to the first connection terminal, and one of the two lead wires connected to the other end side is connected to the second connection terminal. By connecting the other to the third connection terminal, a 1-gauge 3-wire physical quantity detection circuit is formed.
Of the two strain gauges, the two lead wires of one strain gauge are connected to the first connection terminal and the second connection terminal, respectively.
By connecting the two lead wires of the other strain gauge to the second connection terminal and the third connection terminal, respectively, a physical quantity detection circuit of a two-gauge method is formed.
One of the two leads of the voltage source, connected to said first connection terminal and connecting the other to the second connection terminal, the physical quantity detection circuit for detecting the voltage of the voltage source Formed,
One of the two leads of the thermocouple, connect the other connected to the first connection terminal to said second connection terminal, characterized in that the physical quantity detecting circuit including a thermocouple is formed The connection terminal for a physical quantity detection sensor according to claim 1. Of the four strain gauges connected to the multi- core connector, one of the two lead wires of the first strain gauge is connected to the first connection pin, and the other is connected to the second connection pin. And
One of the two leads of the second strain gauge is connected to the second connecting pin, the other is connected to the third connecting pin, and one of the two leads of the third strain gauge is connected. Connect to the third connection pin and connect the other to the fourth connection pin.
By connecting one of the two lead wires of the fourth strain gauge to the fourth connection pin and the other to the first connection pin, a physical quantity detection circuit of the full bridge method is formed. The connection terminal for a physical quantity detection sensor according to claim 1 or 2, characterized in that. An on / off switch and a changeover switch are provided at one or more points of the internal circuit, and two or more measurement modes are formed to form a circuit corresponding to the binary state of the on / off switch and the changeover state of the changeover switch. The connection terminal for a physical quantity detection sensor according to claim 1, wherein a predetermined wiring is made with a physical quantity measuring device configured to be able to determine the value of the physical quantity in a desired mode. .. The connection terminal for a physical quantity detection sensor according to claim 1, wherein the dedicated connector is a multi-core type connector. A claim, wherein the common plurality of individual connection terminals is characterized in that any one of three screw terminals, a solder terminal, or a one-touch pin terminal is arranged in a terminal block in close proximity to the connector. The connection terminal for the physical quantity detection sensor according to 1. The connection for a physical quantity detection sensor according to claim 1 or 3, wherein the physical quantity detection circuit in the predetermined mode is a full bridge detection circuit formed by including strain gauges on the four sides of the bridge circuit. Terminal. The physical quantity detection sensor in the predetermined mode is a strain gauge type converter configured by using a strain gauge that changes the resistance value in response to any of pressure, acceleration, vibration, displacement, load, and torque. The connection terminal for a physical quantity detection sensor according to claim 1 or 7.

Images